The invention relates generally to gas turbine combustors and more specifically to a lean premixed, radial inflow, multi-annular staged nozzle for a can-annular dual-fuel combustor that dramatically reduces or eliminates combustion dynamics.
Each combustor 14 includes a substantially cylindrical combustion casing 24 which is secured at an open forward end to a turbine casing 26 by means of bolts 28. The rearward end of the combustion casing 24 is closed by an end cover assembly 30 which may include conventional supply tubes, manifolds and associated valves, etc. for feeding gas, liquid fuel and air (and water if desired) to the combustor 14. The end cover assembly 30 receives a plurality (for example, five) of fuel nozzle assemblies 32 (only one shown for purposes of convenience and clarity) arranged in a circular array about a longitudinal axis of the combustor 14. Each fuel nozzle assembly 32 is a substantially cylindrical body having a rearward supply section 52 having inlets for receiving gas fuel, liquid fuel and air (and water if desired) and a forward delivery section 54.
Within the combustion casing 24, there is mounted, in substantially concentric relation thereto, a substantially cylindrical flow sleeve 34 which connects at its forward end to the outer wall 36 of the transition duct 18. The flow sleeve 34 is connected at its rearward end by means of a radial flange 35 to the combustion casing 24 at a butt joint 37 where fore and aft sections of the combustor casing 24 are joined.
Within the flow sleeve 34, there is a concentrically arranged combustion liner 38, which is connected at its forward end with the inner wall 40 of the transition duct 18. The rearward end of the combustion liner 38 is supported by a combustion liner cap assembly 42 which is, in turn, supported within the combustion casing 24 by a plurality of struts 39. It will be appreciated that the outer wall 36 of the transition duct 18, as well as that portion of flow sleeve 34 extending forward of the location where the combustion casing 24 is bolted to the turbine casing 26 (by bolts 28) are formed with an array of apertures 44 over their respective peripheral surfaces to petit air to reverse flow from the compressor 12 through the apertures 44 into the annular space between the flow sleeve 34 and the liner 38 toward the upstream or rearward end of the combustor 14 (as indicated by the flow arrows shown in
The combustion liner cap assembly 42 supports a plurality of premix tubes 46, one for each fuel nozzle assembly 32. More specifically, each premix tube 46 is supported within the combustion liner cap assembly 42 at its forward and rearward ends by front and rear plates 47, 49, respectively, each provided with openings aligned with the open-ended premix tubes 46. The premix tubes 46 are supported so that the forward delivery sections 54 of the respective fuel nozzle assemblies 32 are disposed concentrically therein.
The rear plate 49 mounts a plurality of rearwardly extending floating collars 48 (one for each premix tube 46), arranged in substantial alignment with the openings in the rear plate 49. Each floating collar 48 supports an annular air swirler 50 in surrounding relation to the respective fuel nozzle assembly 32. Radial fuel injectors 66 are provided downstream of the swirler 50 for discharging gas fuel into a premixing zone 69 located within the premix tube 46. The arrangement is such that air flowing in the annular space between the liner 38 and the flow sleeve 34 is forced to again reverse direction in the rearward end of the combustor 14 (between the end cap assembly 30 and sleeve cap assembly 42) and to flow through the swirlers 50 and premix tubes 46 before entering the burning zone or combustion chamber 70 within the liner 38, downstream of the premix tubes 46. Ignition is achieved in the multiple combustors 14 by means of a spark plug 20 in conjunction with cross fire tubes 22 (one shown) in the usual manner.
In power plant design, reducing emissions of harmful gases such as nitrogen oxides (NOx) into the atmosphere is of prime concern. Low NOx combustors employing lean premixed combustion with a plurality of burners attached to a single combustion chamber, such as described in
Diffusion gas fuel and liquid fuel are typically injected via orifices located on the flat end face of the fuel nozzle. During low NOx (premix) operation, fuel is injected through the fuel injectors and mixes with the swirling air in the flow tube. The diffusion and liquid fuel circuits are typically purged with air during premix operation to keep flame gases out of the passages. The combustion flame is stabilized by bluff-body recirculation behind the fuel nozzle and swirl breakdown, if swirl is present. With premixed systems, strong pressure oscillations are typically produced as a result of combustion instabilities. The combustion instabilities are believed to be related to the shedding of spanwise vortices from the bluff end of the fuel nozzle. These pressure oscillations can severely limit the operation of the device and in some cases can even cause physical damage to combustor hardware. Furthermore, the flow of purge air through the diffusion and liquid fuel circuits is injected directly into the recirculation zone. This direct injection reduces the local temperature and strength of the recirculation, producing an adverse effect on flame stability. Accordingly, there is a need for a low NOx combustor, which reduces pressure oscillations and avoids the adverse effects of injecting purge air directly into the recirculation zone.
As previously described, these contemporary heavy-duty industrial Dry-Low NOx (DLN) can-annular gas turbine combustors typically employ a multiplicity (or gang) of premixing nozzles interfaced with a can combustor liner using a flat or angled cap/dome assembly. Multiple nozzles are required for the mixing and the staging of fuel to achieve turndown and performance throughout the intended operability and design space. This approach, however, creates a complicated and expensive assembly.
Also, distributing the air and fuel uniformly to the cluster of premixing fuel nozzles at the headend is difficult and generally results in less than ideal, uniform air flow to all the nozzles, or a substantial amount of parasitic pressure drop/loss. Swirl-stabilized, lean premixed (LP) combustion tends to be highly susceptible to combustion-driven oscillations (dynamic instability) compared to conventional, diffusion style combustion.
Historically, in the gas-turbine-engine industry, flame temperature (or primary zone temperature) has been reduced in LP systems to reduce NOx emissions. As acceptable NOx exhaust emissions levels have been decreased down to single digit parts-per-million (ppm) levels (driven primarily by new government regulations) flame temperature has been driven very near to the lean-blowout (LBO) limit, at least for fuels with a high methane content. For such lean mixtures, slight, periodic variations in local fuel-to-air mixture ratio results in relatively large, periodic variations in local heat release and heat-release rates—even including local, periodic flame extinction. Discrete, oscillation frequencies (or tones) can grow in amplitude when the heat-release fluctuations are constructively in phase with the acoustic pressure fluctuations encountered inside the combustion chamber.
As present LP combustors become leaner and more spatially uniform to meet increasingly lower NOx emissions, and are increasingly required to meet those emission targets while running on a broadening range of fuels, the risk of encountering unacceptably high levels of combustion dynamics goes up for a given system.
Although, large single-nozzle DLN, low-NOx can-annular gas-turbine combustion systems have been tried previously, most have failed due to operability, durability, and emissions problems. Lack of smart, tunable operating parameters and a lack of multiple independent combustion staging zones has led the industry to embrace modular, multi-nozzle (gang) configurations. Multi-nozzle designs allow for the staging or skewing of fuel distribution to subgroups of nozzles to not only facilitate lightoff and turndown, but to provide a tunable operability parameter to skirt dynamics (or oscillations) encountered while running in the design, operating space.
The downside of skewing the fuel distribution in the combustor is that hotter temperature zones are created that drive NOx production. Thus, if too much skewing is required to squash dynamics or instability, the breaching of regulatory NOx emissions limits could occur, possibly putting the unit out of commission. LP combustion dynamics in industrial gas turbines are typically abated passively in a few ways, usually a trial and error process, which can be expensive and uncertain. Some of the methods are listed below: 1) shifting the fuel injection points to alter the fuel transport time from the point of injection to the flame front, 2) changing the fuel injection orifice sizes to alter the pressure drop and the acoustic impendence across the holes, and 3) modifying chamber or nozzle geometries (e.g., diameters, angles, lengths) to affect vortex shedding, frequencies and amplitudes, or flame shape in the chamber.
These methods attempt to force any perturbations in heat release to be out of phase (or destructively in phase) with pressure or acoustic perturbations in the combustion chamber. Combustor dynamics have also been reduced or eliminated by adding acoustic damping (e.g., Helmholtz resonators or quarter-wave tubes) to the combustion system. In the past, the above methods have tended to be considered and exercised ex post facto to discovering high combustor dynamics, instead of designing for them proactively during the initial design phase in the program.
Accordingly, there is a need to provide a simpler, scalable, less-expensive LP combustor that is fundamentally much less likely, in a statistical and absolute sense, to excite or drive discrete combustion oscillations at any loading within the design/operating space, while having an above average tolerance to fuel-mixture quality. Assuming that if the above solution were found, and that, consequently, the risk of ever encountering discrete dynamics in the given design operating space were greatly reduced, then the efficiency and probability of tuning for the minimum emissions for a given system would be greatly increased. Essentially, dynamics would no longer be such a significant and intractable part of the overall combustor-design procedure.
The present invention relates to an apparatus and method creating three independent combustion zones in a gas turbine combustor with a lean premixed, radial inflow, multi-annular, staged nozzle, thereby providing stable combustion with low nitrogen oxide (NOx) emissions.
Briefly in accordance with one aspect of the present invention, a lean premixed, radial inflow, multi-annular, staged nozzle for creating three independent combustion zones within a can-annular, dual-fuel gas turbine combustor is provided. The lean premixed, radial inflow, multi-annular, staged nozzle (hereinafter referred to as a single large radial nozzle) includes a pilot zone fueled by a center cartridge; a flame holder zone fueled by an inner main gas fuel; a main flame zone fueled by an outer main gas fuel; a main radial swirler for mixing a portion of incoming air to the nozzle with the inner main gas fuel supply and the outer main gas fuel supply; an endcover; and means for controlling the ratio of pilot gas fuel supplied, inner main gas fuel supplied, and an outer main gas fuel supplied.
In accordance with another aspect of the present invention, a can-annular, dual-fuel combustor for a gas turbine engine is provided. The combustor includes a lean premixed, radial inflow, multi-annular, staged nozzle (hereinafter referred to as a single large radial nozzle), incorporating an outer burner tube and a main radial swirler, mounted on an endcover to a combustor casing. A main combustion zone is provided downstream from the outer burner tube of the single large radial nozzle. A source of compressed air from a compressor source is provided. An air inlet plenum radially surrounds the single large radial nozzle and is bounded radially by an outer wall of the combustor. A diffuser for the compressed air receives the compressed air in a reverse flow path from the compressor and discharges the compressed air at a restored pressure to the inlet plenum. A fairing mounted atop the main radial swirler and surrounding a portion of the outer burner tube is provided for smoothing air flow from the diffuser to the air inlet plenum.
In accordance with a third aspect of the present invention, a method is provided for utilizing a lean premixed, radial inflow, multi-annular, staged nozzle (hereinafter referred to as a single large radial nozzle) with independent combustion zones, wherein the single large radial nozzle includes a pilot zone, a flame holder zone and a main zone, within a gas turbine combustor for providing stable combustion with low Nitrogen Oxide (NOx) emissions. The method includes providing a large supply of air to the nozzle; intra-nozzle staging; breaking up of the heat release into a multiplicity of discrete zones in space; distributing the heat release in time; and ventilating a downstream central recirculation zone.
These and other features, aspects, and advantages of the present invention will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
The following embodiments of the present invention have many advantages, including several innovative and unique features: (1) allowing for multiple (e.g., six) premixing nozzles (per can) and a combustor-chamber cap to be replaced with just one large radial nozzle and a liner modification, thereby achieving a significant part-count reduction, a cost savings, and a dramatic simplification of the combustor's head-end; (2) using a dome-diffuser design to backside, convectively cool the liner's dome, while, simultaneously recovering static pressure prior to premixing the fuel and air in the large radial nozzle, thereby causing less parasitic pressure loss and malting more air available for premixing; (3) providing the capacity to rapidly (e.g. <3 msec) and thoroughly vaporize and mix large quantities of fuel (˜2 lbm/sec) and air (˜60 lbm/sec) at a relatively low pressure drop (e.g., <4%); and (4) using either gas fuel or liquid fuel, it is more robust dynamically and less prone to combustion-driven oscillations than contemporary lean-premixed (LP) gas-turbine combustion systems, by strategically distributing or smearing out both the heat release (in time and space) and fuel transport time in the chamber, while still delivering the necessary system turn-down performance and low exhaust emissions.
The effect of the design is multifaceted: (1) the replacement of five or more nozzles per can with one for a dramatic cost and parts-count reduction; (2) the dramatic reduction or even complete elimination of combustion dynamics/oscillations at discrete frequencies within industrial gas turbine combustion chambers, while maintaining required emissions levels; (3) gas and liquid fuels flexibility, which is tied to the success of combustion dynamics improvement; (4) DLN with liquid fuels like No. 2 diesel oil, while eliminating the need for water injection and high-pressure atomizer air; and (5) low single-digit (ppmv) noxious emissions.
To go from a multi-nozzle arrangement to a large single nozzle, successfully, requires intra-nozzle staging. A zone of angled v-gutter flame holders, used in this design, provides a region for fuel staging within the main premixing nozzle. For example, biasing the fuel-air ratio to be richer near the hub (or centerbody) in the premixer, can allow a central flame-holder zone to burn at a higher equivalence ratio relative to the bypassing flow, which may be advantageous (or even necessary) for ignition, machine acceleration, low-load operation, or handling sudden load transfers. Biasing the fuel-air ratio, in conjunction with other staging features (like a premixed pilot), will allow for a single large radial nozzle to replace multiple nozzles (e.g., six), per can, in gas turbine combustion systems—which would amount to a significant part-count reduction and cost savings for the combustion system and the engine as a whole. Combustion dynamics reduction would be achieved while maintaining or even reducing noxious exhaust emissions (e.g., unburnt hydrocarbons (UHC), NOx, and carbon monoxide (CO)), relative to the firing temperatures encountered in the design space.
The lean premixed, radial inflow, multi-annular staged nozzle (hereinafter referred to as a single large radial nozzle), by design, is less likely to excite combustion-driven, discrete oscillation frequencies when the set fraction (e.g., about 33% of the nozzle's reactants) of well-mixed reactants is redirected to burn as an angled array of discrete, v-gutter zones upstream of the main chamber. The array of axial jets passing through the conical v-gutter-pack structure abates discrete dynamics and improves emissions in a few ways.
First, the array breaks up the heat release into a multiplicity of discrete reaction zones in space, each reacting at spatial scales that are much smaller than that of the overall combustion chamber. This effectively limits the amount of energy release that can constructively couple at a particular acoustic, resonant frequency within the chamber.
Second, the angled v-gutters create a multiplicity of fuel transport times, which distributes (or smears out) the heat release in time. That is, each point along the v-gutter length has its own associated transport time: the time between the point(s) of fuel injection and the point(s) of burning. This, too, effectively limits the amount of heat-release energy that can constructively couple at a particular chamber acoustical, resonant frequency.
Third, the function of the de-swirler pack is the “ventilation” of the downstream central recirculation zone (CRZ), resulting from vortex breakdown. From the central cone, the expanding array of jets injects non-swirling, axial momentum directly into the CRZ, which reduces the size and the bulk residence time of the CRZ. This, in turn, reduces nitrogen oxide (NOx) production by reducing the average time that the combustion-product molecules spend at the primary-zone (flame) temperature inside the combustor. The concept of “time at temperature” for NOx production becomes increasingly significant at flame temperatures above 2900 F, where the Thermal NOx (or Zeldovich) mechanism begins to accelerate and its contribution to overall system NOx levels begins to significantly increase.
The nozzle further provides an anti-coke design for operation with diesel liquid fuel that requires no water and no atomizer air. Aspects of the design prevent fuel gallery coking through an insulated fuel gallery wall for high reliability. Liquid fuel is rapidly atomized and thoroughly dispersed into the premixer airflow, keeping it off of hot premixer surfaces to vaporize and mix quickly with the air. The liquid injection scheme does not adversely impact gas operation. Eliminating the need for water injection and high-pressure atomizer air further provides a cost saving.
Complete fuel-air mixing is rapid (approximately 2 msec), thorough (greater than 97%), and requires a low premixer differential pressure (˜2%), thereby reducing the required premixer residence time to create a shorter, more compact design and to stay below the auto-ignition time of diesel at “advanced” gas turbine conditions.
Several further aspects and advantages of the invention will become clear in the description. Turndown capability is enhanced via fuel staging (3 pseudo-independent combustion zones). Using a backside-cooled dome eliminates the need for liner cooling air in the flame zone.
Also, axi-symmetric, radial combustion staging does not subject the combustor liner to asymmetric loading, thereby providing improved combustion liner durability.
Further, improved internal premixer flame-holding resistance/margin: flow is accelerated throughout premixer nozzle; bulk velocity is kept above about 300 ft/sec.
A v-gutter lean angle (radial-axial plane) and the de-swirler vane profile were chosen as the two parameters to optimize. The v-gutter lean angle was varied between 30- and 60-deg. to maximize the lean angle, while still generating a well defined, continuous v-gutter wake to support an independent combustion zone. For non-reacting CFD, the 40-deg. configuration was the largest angle that still produced a continuous v-gutter wake with other nozzle features being held constant. The de-swirler vane profile was successfully adjusted/optimized by aligning the inlet vane angle with the incoming swirling flow and using the cascade geometry to accelerate the flow through the pack; thus, preventing any flow separation in the pack.
Within the combustion casing 105, there is mounted in substantially concentric relation thereto a flow sleeve 106. Within the flow sleeve 106, there is concentrically arranged combustion liner 110, connected at its forward end 112 to the inner wall of the transition liner (not shown), into which it plugs. The rearward end of combustion liner 110 forms a truncated conical dome 111 on a main combustion chamber 114, the truncated conical dome 111 being open at its center to fuel and combustion products flow from the large radial nozzle 120 and further mating with the outer burner tube 113 of the large radial nozzle 120.
Air for the combustion process may be drawn from the air compressor into the transition piece (as previously described with respect to
The large radial nozzle 120 further includes a main radial swirler 140, a gas pilot nozzle 150, a central flame holder with a v-gutter flame holder 160, and an outer flame holder 170. The central flame holder 160 and the outer flame holder 170 open on their forward end into the main combustion chamber 114.
The endcover 130 may be a generally cylindrical-shaped flange designed to mate with a combustor casing 105 and support the radial nozzle assembly 120 within the combustor 100. The aft surface 135 of the endcover 130 provides penetrations for dual-fuel (gas and liquid fuel) as well as for the gas pilot nozzle 150. A outer main gas supply 190, a inner main gas supply 190 and one of a plurality of liquid gas connections 195 are shown in
The endcover assembly 130 includes an endcover plate 205 with an aft section 201, a forward section 202 and a central cavity 203. A main radial swirler 140 includes a backplate 240, a plurality of swirl vanes 250 and a central hub 260 with a central cavity 265 within. The backplate 240 is bolted at mounting surface 241 to endcover plate 205.
A central flame holder 160 is mounted atop the central hub 260. A center hub 285 of the central flame holder 160 mates with the central hub 260 of the main radial swirler 140 to support the central flame holder 160 radially and axially. Radial vanes 360 support inner burner tube 300 from center hub 285. A plurality of v-gutters 290 extend between the inner burner tube 300 and the center hub 285. A central cavity 278 is formed within center hub 285. Atop the swirl vanes 250 of the main radial swirler 140, an outer flame holder 170 with cylindrical outer burner tube 175 is mounted with a base section 180 that flares outward radially and attaches with bolts 183 to the top of the swirl vanes 250. The downstream end 178 of outer burner tube 175 also flares outward and is reinforced to provide support for the conical dome 111 (
Two independent gas fuel supplies may be connected to the endcover plate 205. The aft section 201 includes an outer main gas penetration 215 attached to an outer main gas supply inlet pipe 216 with outer main gas inlet flange 217 for connection to the outer main gas fuel supply (not shown). The aft section 201 also includes an inner main gas penetration 220 with a fitting 219 for connection to an inner main gas supply (not shown). The endcover plate 205 may also include a plurality of liquid fuel supply penetrations 243 located concentric to the central axis 200 of the nozzle.
The inner main gas penetration 220 is connected to a inner main gas gallery 330 in the endcover plate 205. The inner main gas gallery 330 defines an annular chamber concentric with the central axis 200 of the nozzle. The inner wall 317 and outer wall 318 of the inner main gas gallery 330 may be concentric to the central axis 200 of the nozzle. The inner main gas gallery 330) is located radially between the outer main gas channel 310 and the central cavity 203. The inner wall 317 and outer wall 318 of the inner main gas gallery are radially located, such that the open upper end 319 of the inner main gas gallery 330 communicates with corresponding inner main gas channels 680 (
Liquid fuel supply penetrations 243 extend axially through the aft section 201 of the endcover 205, communicating with a main liquid fuel gallery 244. The main liquid fuel gallery 244 defines an annular chamber concentric with the central axis 200 of the nozzle and sealed except for liquid fuel supply penetrations 243 and liquid fuel delivery penetrations 246. The main liquid fuel gallery 244 is located radially to align with the liquid fuel supply penetrations aft 243 and the liquid fuel delivery penetrations 246 forward on the endcover plate 205. The liquid fuel delivery penetrations 246 extend through the forward section 202 of the endcover 205 to mate with corresponding liquid fuel delivery penetrations 247 in the main radial swirler backplate 240 leading to atomizers 248 for the liquid fuel in the main swirler backplate 240. The walls of the main liquid fuel gallery 244 and the liquid fuel supply penetration and liquid fuel delivery penetration 246 in the endcover 205 and fuel delivery penetrations 247 in the backplate 240 may be provided with an insulated lining 249 to keep wall temperatures below 290 degrees F. where coking of diesel liquid fuel begins. Fittings 218 are provided external to the liquid fuel supply penetrations for connection to the liquid fuel supply.
Because the endcover plate 205 and the main swirler backplate 240 mate in a metal to metal seating surface 241, provision is made to isolate potential leakage from the fuel cavities along the seating surfaces 204, 241. Three annular recesses (
The main radial swirler 140 includes a backplate 240 with an integral central hub 260, a plurality of main swirl vanes 250 mounted on the backplate 240 and projecting orthogonally to the backplate 240 (downstream toward the combustion zones), a central cavity 265 to accommodate the gas pilot nozzle 150 and a series of internal passages within the backplate and main swirl vanes 250 to provide for flow of fuel and air.
The backplate 240 comprises a cylindrical shaped flange centered on the central axis 200 of the nozzle. A base surface 241 of the backplate 240 is sized radially to mate with the forward surface 204 of the endcover plate 205. The mounting surface 242 of the backplate incorporates a plurality of recesses 371 accommodating bolt holes 372 around the periphery the backplate 240. The bolt holes 372 extend through to the base surface 241 of the backplate 240 and align with the bolt holes 209 on the forward 204 surface of the endcover plate 205. The mounting surface 242 of the backplate 240 provides for mounting a plurality of main swirl vanes 250 and housing injection points for fuel into an air flow steam within the main radial swirler 140
The plurality of main swirl vanes 250, each including a solid metal airfoil 610, may be mounted orthogonal to the backplate 240 and project axially toward the combustion zones. The main swirl vanes 250 may be mounted inboard radially from the peripheral bolt hole recesses 371 and outboard radially from the central hub 260. A leading edge 615 of each airfoil projects generally outward radially and a trailing edge 620 projects generally inward radially. The axis 625 of each airfoil may form a predesignated acute angle α (approximately 15°) 630 with a radius 635 from the central axis 200 of the nozzle. While the leading edge 615 of the airfoil 610 forms a curved surface, the side surfaces 640, 641 of the airfoil 610 may form a straight-fine taper to the common linear trailing edge 620. The bottom surface 645 and top surface 650 of the airfoil 610 form plane surfaces. The bottom surface 645 may be mounted to the mounting surface 242 of the backplate 240 by welding or other suitable process.
A plurality of injection points 655 for outer main gas fuel are provided along a radius concentric with the central axis 200 of the nozzle, on one side surface 640 of the airfoil 610, just inboard of the curved leading edge 615. The injection of outer main gas fuel is provided approximately normal to the airflow 660 passing between the adjacent swirl vanes. However, injection points 655 may also be provided on both side surfaces of the airfoil and at other locations than included in the present embodiment. The injection points may be approximately evenly spaced axially along the side surface 640 of the airfoil 610 to permit even distribution of the outer main gas fuel into the airflow 660 between the airfoils 610 in a circumferential premixing space 605. The airfoils 610 further include an internal fuel cavity 665 supplying the injection holes 657. The fuel cavity 665 may be a generally cylindrical-shaped hole rising from the base surface 241, axially into the airfoil 610 and stretching in proximity to and communicating with the injection holes 657. The fuel cavity 665 directs outer main gas fuel from the fuel cavity 310 in the endplate 205. The injection holes 657 within each airfoil 610 extend in a radial direction with respect to the cylindrical fuel cavity 665 to supply fuel to the injection points 655. The top surface 650 of each airfoil 610 may further include a tapped hole 670 for securing the outer burner tube 175 to the main swirl vanes 250.
Inner main gas penetrations 680 (
During gas operation as described above, gas fuel is injected into the air flow of the main radial-swirler 140 from a multiplicity of injection points 655 located axially along the sidewalls 640 of the airfoils 610 and from injection points 695 on the mounting surface 242 of the backplate 240. The main gas fuel is fed from two independent feed sources as shown in
A plurality of liquid fuel injection points 245 are also provided on the mounting surface 242 of the backplate 240 for operation on liquid fuel. The liquid fuel injection points 245 are positioned atop the liquid fuel delivery channels 246 in the backplate 240. The liquid fuel channels 246 in the backplate 240 may include a thermal insulating layer 249. The liquid fuel injection points 245 are concentric with the central 200 axis and may be positioned to inject liquid fuel in the annular swirl volume 255 at approximately the locus of the trailing edges 620 of the airfoils 610. In an exemplary arrangement, six liquid fuel injection points 245 are provided circumferentially equidistant around the mounting surface 242. Each liquid fuel injection point 245 is provided with a tip 252 that includes an atomizer 248 of a conical shape, that screws into threads 253 for the liquid fuel delivery channel 247. The atomizer 248 sprays liquid fuel into the air flow in an axial direction normal to the mounting surface 242.
Airflow from diffuser 116 flows into inlet plenum 117. The main swirl vanes 250 establish a flow path 660 for incoming air from the inlet plenum 117 for the combustor. About 95% of the air entering the nozzle flows between the main swirl vanes 250. The incoming air, having had outer main gas injected from the airfoils 610 and inner main gas injected from the injection points 690 on the mounting surface 242 and/or liquid fuel injected from the atomizers 248, is directed by the air foils 610 to swirl in a counter-clockwise direction (viewed from the combustion end) through the annular swirl volume 255 (the volume between the swirl vanes and the central hub). Within the annular swirl volume 255, the continued swirling further mixes the fuel with the air.
The central hub 260 comprises an outer truncated cylindrical conical surface centered on the central axis 200 of the nozzle to minimize flow resistance to a circumferential flowing fuel-air mixture from the main swirl vanes as it rises up into the central flame holder 160. The central hub 260 forms a smooth surface rising from the mounting surface 242 of the backplate 240 and sloping concave inward to form a radial and axial support for the central flame holder 160. Specifically, at its truncated upper reach, the central hub 260 provides an outer annular support ledge 273 for the central flame holder 160. The inner surface 263 of the central hub 260 defines a cavity 265 that accommodates a gas pilot nozzle 150 and includes an internal flow path for air to the gas pilot nozzle 150. The internal surface 263 of the central hub further includes an inner annular mounting ledge 274 for the central flame holder 160.
The series of internal passages within the backplate includes passages for outer main gas from the outer main gas gallery in the endcover to the swirl vanes; for the inner main gas gallery in the endcover to gas injectors on mounting surface of the backplate; for liquid fuel from the liquid fuel delivery penetrations in the endcover to atomizers on the mounting surface of the backplate; and air passages from the circumferential outer edge of the backplate to the central cavity for cooling and pilot premix air to the radial nozzles center/core.
The internal passage 680 for inner main gas to the inner main gas injector tips 695 on the mounting surface 242 of the backplate 240 may include orifices 685 in each passage to control gas flow rates to the gas injector tips 695. The outer circumferential surface 257 of the backplate 240 includes a plurality of radial feedholes 275 directed inward to the central cavity 265 for feeding a flow of cooling air and pilot premix air to the central cavity 265. The axial passages within the backplate for outer main gas 270, inner main gas 680, and liquid fuel 247 are situated in circumferential locations between the various radial feedholes 275.
The central flame holder 160 may include a center hub 285, a central cavity 278, a deswirler 280, and a plurality of v-gutters 290, an inner burner tube 300 and a support tower 295.
As airflow from between the main swirl vanes 250 is forced into a rotational flow within the annular swirl volume 255, the only exit path is downstream. About 30% of the fuel-air mixture swirled in the main radial swirler 240 enters the central flame holder 160. The central flame holder 160 includes the support tower 350 that sits atop the central hub 260 of the main radial swirler 240. The support tower 350 mates with the outer support ledge 273 and inner support ledge 274 of cylindrical support hub of the central hub 260 to provide axial and radial support for the central flame holder 160. Support arm 355 of the support tower 300 seats on the outer support ledge 273 and the inner support ledge 274. A central cavity 280 within the support tower 295 and the center hub 285 may accept the gas pilot nozzle 150.
Referring to
Referring to
A v-gutter 290 is provided at the downstream end of each radial vane 360. The v-gutter 290 comprises a v-shaped element 375 with the open end 376 facing downstream. A vertex 377 of the v-shaped element 376 is attached to and extends through the annular tip 380 of the center hub, along the downstream edge of radial wall 360 and through the tip 385 of inner burner tube 300.
An outer flame holder 170 comprises a generally cylindrical outer burner tube 175, which flares at an upstream end to form a annular seating surface for mating with the main swirler. The cylindrical tube radially surrounds and extends towards the combustion chamber beyond the central flame holder 160. The downstream end 190 of the outer burner tube 175 is reinforced. Ledge 195 provides a seating surface for engagement with the conical dome 111 (
As a means of achieving lightoff, combustor turndown, and improving stability, a central gas pilot nozzle 150 is located inside the conical flame-holder volume at the upstream, smallest-diameter end. The gas pilot nozzle 150 provides a center cartridge 155 which may include an igniter/flame detector and a liquid gas pilot.
The roughly 5% of airflow to the radial nozzle that enters through radial flowholes 275 in the circumferential surface 257 of the backplate 240 for the main radial swirler 140 is split internally. About 80% of this air flows forward through a air supply annulus between the inner wall of the central hub central cavity 265 and an outer surface 812 of an annular shell 810 of the gas pilot nozzle 150 to an annular axial-swirled gas-pilot premixer 855. The remainder of the air passes through a plurality of radial feed holes 875 in the annular shell 810 into the center cartridge to be used for liquid-pilot atomization and cooling and purging of the center-cartridge tip.
The gas pilot nozzle 150 comprises a body 805 with annular shell 810 that may be breech-loaded into the central cavity 203 of the nozzle 140 through the endcover plate 205. The annular shell 810 includes aft flange 815 at its aft end with a plurality of bolt holes 816 for mounting its forward surface 817 to the seating ledge 210 within the central cavity 203 of the endcover 205. The aft flange 815 is also provided with a center hole 818 for insertion of the center cartridge 155 and includes an elevated surface 819 on the rear surface 820 about the center cavity incorporating tapped holes 821 for bolting the center cartridge 155 to the gas pilot aft flange 815. The aft flange 815 is also provided with a penetration 230 for connection to a pilot gas fuel supply for gas pilot operation.
The gas pilot nozzle body 805 extends through the central cavities 203, 265, 278 of the nozzle 120 and into the cylindrical hub 370 of the central flame holder 160. The gas pilot annular shell 810 tapers in steps from aft end to forward end. The annular shell 810 includes lower shell 835, a tapered shell 840, a central shell 845 and a tapered head 850.
An annular gas pilot airflow space 864 is also defined between the inner wall 368 of the cylindrical hub 370 and the inner wall 296 of support tower 295 with the outer surfaces 842, 847 of the tapered shell 840 and the central shell 845. Air from inner radial ends 277 of the central radial feedholes 275 in the backplate 240 enters the gas pilot airflow space 864 and flows forward axially to axial-swirled gas-pilot premixer 855.
The penetration 230 in aft flange 815 for pilot gas fuel supplies internal pilot gas fuel cavities 862 in the annular shell 810. The internal pilot gas fuel cavities 842 within the lower shell 835 supply pilot gas fuel to the annular pilot gas space 866 between the inner wall of annular shell 810 and outer surface 872 of center cartridge 155. The tapered head 850 extends in close proximity to the cylindrical hub 370, thereby forming a gas pilot annulus 825 between the outer surface 830 of the tapered annular head 850 and the inner surface 368 of the cylindrical hub 370. A plurality of pilot gas fuel holes 860 extend radially through the annular shell at the upstream entrance between adjacent axial mixing vanes 857 providing pilot gas fuel injection points. The forward portion of the central shell 845 accommodates a plurality of axial mixing vanes 857 in the general shape of airfoils on the outer surface 847 for mixing gas pilot fuel and air moving downstream in the airflow space 864, thereby constituting the annular axial-swirled gas-pilot premixer 855.
The center-cartridge 155 includes cylindrical body 405 mounted on a rear flange 224. The center cartridge 155 is inserted into the central cavity 203 of the gas pilot nozzle body 805 and bolted through the rear flange 224 onto the raised rear surface 820. The rear flange 224 provides an axial penetration for connections to an igniter and flame detector 236 and on its circumferential surfaces, a radial penetration 232 for liquid pilot fuel and a radial penetration 234 for an air The center cartridge 155 is aligned with central axis 200 of the nozzle.
The foregoing has described a single large radial nozzle for a gas turbine combustor that provides major improvements in operation over multi-nozzle designs. First, the intra-nozzle combustion staging provided by the nozzles premixer design, especially, the conical, de-swirled, v-gutter flame-holder in conjunction with controllable outer main gas fuel injection paths and inner main gas fuel-injection paths, is a unique aspect of this design. This aspect allows multiple nozzles (per combustor) to be replaced by one, resulting in major cost and part-count savings. Second, combustion dynamics/oscillation abatement is created by the smearing out of fuel transport times and heat release in the chamber is a novel manner. This unique property additionally may allow a broader range of fuels to be burned without needing to modify or replace hardware. Finally, the combustor headend design and the way the nozzle is integrated with the combustor dome in creating an annular dome diffuser that recovers pressure while convectively cooling the backside of the liner's dome without a need for introduction of a separate cooling air source provides increased simplicity with functionality.
Presently, the inventive nozzle has been sized for the GE 9FB heavy-duty industrial engine; however, it can be scaled up or down in size to work for almost any combustor annular design (e.g., 7H, 9H, 7FB, 7FA, 9FA, 6C, etc.). The design could be retrofitted to an existing package, or it could be introduced as a new product offering.
While only certain features of the invention have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention.